High-strength aluminum-based composites reinforced with BN, AlB2 and AlN particles fabricated via reactive spark plasma sintering of Al-BN powder mixtures
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- 作者:K.L. Firesteina ; const@firestein.ru ; S. Corthaya ; A.E. Steinmana ; A.T. Matveeva ; A.M. Kovalskiia ; I.V. Sukhorukovaa ; D. Golbergb ; golberg.dmitri@nims.go.jp ; D.V. Shtanskya ; shtansky@shs.misis.ru
- 关键词:Mechanical characterization ; Electron microscopy ; Composites ; Aluminum alloys ; Powder metallurgy ; Hardening
- 刊名:Materials Science and Engineering: A
- 出版年:2017
- 出版时间:10 January 2017
- 年:2017
- 卷:681
- 期:Complete
- 页码:1-9
- 全文大小:1345 K
- 卷排序:681
文摘
Light (density <2.7 g×cm−3) yet strong (tensile strength >350 MPa) metal matrix composites (MMCs) are highly anticipated for aerospace and automotive industries. The MMCs application fields can be significantly expanded if they possess enhanced strength at elevated temperatures also. In the present study, Al-based composites loaded with either micro- or BN nanoparticles (BNMPs and BNNPs) with up to 10 wt% of BN phase were produced via spark plasma sintering (SPS) of ball-milled Al-BN powder mixtures. A dramatic increase in the composite tensile strength compared to pure Al samples (up to 415%) was demonstrated during tensile tests both at 20 °C and 500 °C. BNMPs were found to be a more preferred additive compared with BNNPs due to the formation of more homogeneous and uniform morphologies within the ball-milled powder mixtures and resultant SPS products. The most impressive tensile strength of 170 MPa at 500 °C was achieved for an Al-7 wt% BNMPs SPS composite, as compared to a value of only 33 MPa for a pure Al SPS-produced sample. The reinforcement mechanism was uncovered based on detailed X-ray diffraction analysis, differential scanning calorimetry, Raman spectroscopy, scanning and high-resolution transmission electron microscopy and energy-dispersion X-ray analysis. Microscale BN, AlB2 and AlN inclusions acting within Al-matrices in the frame of Orowan strengthening mechanism, and pre-formed during ball-milling-induced pre-activation of Al-BN powder mixtures, finally crystallized during SPS processing and ensured the dramatically improved tensile strength and hardness of the resultant composites.